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Originally posted by David King
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If the bobbins differ, figure out the area of a typical turn on each bobbin, and adjust the number of turns so their area-turns products are equal.
Let's try an extreme example, two circular coils, one being three times the diameter of the other. Assume the smaller coil has 1000 turns of thin wire wound on a form 1" in diameter. The area-turns product will be 1000 (Pi/4) 1^2. The other coil is 3" in diameter. How many turns must it have to have equal area-turns product? We will call this unknown turns count "N" and solve, so:
N (Pi/4) 3^2 = 1000 (Pi/4) 1^2
The (Pi/4) terms appear on both sides, and so will cancel, yielding:
N 3^2 = 1000 1^2
Dividing both sides by 3^2 yields:
N = 1000 (1/3)^2, which equals 1000/9, or 111.1 turns.
Now, just for amusement, compute the inductance, using the "single-layer solenoid" and "circular loop" formulas from Inductance - Wikipedia, the free encyclopedia. Each turn is a circular loop. The smaller coil has 1000 such loops, while the larger coil has only 111 turns. Being lazy, I am going to simplify by taking the N^2 term from the w>>1 case of the solenoid formula and apply it to a collection of circular loops; this is in effect a very short solenoid.
The inductance of a 1000 turn coil is (1000/(1000/9))^2=9^2= 81 times greater than that of a 111 turn coil, if they were the same diameter. But they are not the same diameter, so we are not done. Applying the circular loop formula, after some math, a 3" loop has 1.852 times the inductance of a 1" loop, assuming use of #42 AWG wire, with radius 0.00125". So, the net effect is that the smaller coil has 81/1.852= 43.7 times the inductance of the larger coil. This is precisely why the Shur humbucking coil works.
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